Activation energy `(E_(a))` and rate constants `(k_(1) "and" k_(2))` of a chemical reaction at two different temperatures `(T_(1) "and" T_(2))` are realted by

For a reaction AtoB with activation energy E_(a) and rate constant k=Ae^(-Ea//RT) . The rate of the reaction (Rate =k[A] ) increases by increasing the temperature because

What is the ratio of the rate constants K_(1) and K_(2) ?

Write the equation which ralates th rate constants k_(1)and k_(2) at temperatures T_(1) and T_(2) of a reaction.

The rate constant of the chemical reaction doubled for an increase of 10 K in absolute temperature from 298 K. Calculate E_(a) .

The velocities of sound in an ideal gas at temperature T_(1) and T_(2) K are found to be V_(1) and V_(2) respectively. If ther.m.s velocities of the molecules of the same gas at the same temperatures T_(1) and T_(2) are v_(1) and v_(2) respectively then

The rate constant K_(1) of a reaction is found to be double that of rate constant K_(2) of another reaction. The relationship between corresponding activation energies of the two reactions E_(1) and E_(2) can be represented as

The temperature dependence on rate constant (k) of a chemical reaction is written in terms of Arrhenius equation, k=A.e^(-E^(0)//RT) . Activation energy (E^(0)) of the reaction can be calculated by plotting

The rate constants of a reaction at 300K and 280 K respectively are K_(1) and K_(2) . Then

A chemical reaction occurs in three paths having rate constants k_(1),k_(2) and k_(3) respectively. If Ea_(1),Ea_(2) and E_(a_(3) are 4,5 and 8kJ respectivel and overall rate constant k=(k_(1)k_(3))/(k_(2)) . Assuming A_(av)=(A_(1)A_(3))/(A_(2)) the overall energy of activation in kJ is __________